Nondispersion analyzer



Allg- 31, 1954 E. H. wooDHuLL Erm. 2,688,090

NONDISPERSION ANALYZER 2 Sheets-Sheet 1 F'iled Nov. 20, 1952 .Tons/d MM yATTORN'EY ug- 31, 1954 E. H. wooDHuLL ETAL 2,688,090

NoNDIsPERsIoN ANALYZER Filed Nov. 20, 1952 2 Sheets-Sheet 2 Patented Aug. 31, 1954 NONDISPERSION ANALYZER Elliot H. Woodhull, Norwalk, and Glenn E. Tisdale, Noroton, Conn., assignors to The Perkin- Elmer Corporation, Norwalk, Conn., a corporation of New York Application November 20, 1952, Serial No. 321,662

ll Claims. l

This invention relates to radiation instruments for analytical purposes and is concerned more particularly with a novel instrument which embodies the invention disclosed in the (3o-pending application of Williams, Serial No. 293,989, led June 17, i952, but includes additional fea-tures, which will be pointed out hereafter.

The Williams instrument is of the type, in which a pair of beams of radiation travel along separate paths containing media differing in absorptivity and fall upon detecting means. Such instruments necessarily operate with unequal transmission of energy along the two paths and the Williams instrument is provided with means for nulling the detector at one operating point by means of a third beam of radiation, which bypasses the sample to be examined and falls upon the detector coincidentally with the weaker of the nrst two beams. When the instrument is in operating condition with the detector nulled by the third beam, the introduction of the sample results in the detector producing a signal.

The new analyzer uses three beams of radiation in the manner, in which they are used in the Williams instrument, and is provided with a detector, which produces a phase sensitive electrical signal, means, which respond to that signal by varying the intensity of the third beam in such manner that the signal is automatically reduced to zero. The regulation of the amount of energy transmitted to the detector by the third beam is accomplished by adjusting a trimmer for that beam, and means are provided for producing a response corresponding to the adjustment of the trimmer required to reduce the phase sensitive signal from the detector to Zero. Such response may then be employed in operating a, recorder, an indicator, an alarm, etc. In the new instrument, changes occurring in the course of time in the detector and in the gain in the amplifying means employed have no effect on the calibration of the recorder, and the instrument is thus more accurate than prior similar instruments.

Instruments embodying the invention maybe used ier various purposes and a typical instrument is the infrared gas analyzer of the nondispersion type shown in the accompanying drawings, in which l, is a longitudinal. horizontal sectional schematic View of an instrument embodying the invention and utilizing infrared radiation;

Fig. 2 is an elevational view of the chopping device;

3 is an elevational view of a manually operated trimmer;

lll

(Cl. Z50-43.5)

Fig. 4. is a view, partly in vertical elevation and partly in section, of the nulling trimmer of the instrument;

Fig. 5 is a schematic view of a modified form of instrument embodying the invention;

Fig. 6 is an elevational view of the chopper disc used in the instrument of Fig. 5; and

Fig. 7 is a schematic view of another modied form of the new instrument.

In the instrument shown in Fig. l, the source of radiation is a heated coiled filament lll bent to circular form and made of a suitable material, such as nichrcme. The lament is supported on an annular mounting H of insulating material and lies within a housing'generally designated I 2, which includes a concave end section I3 having a highly polished inner surface |311 for multiple reflections of the radiation emitted by the lament. The iilament is supplied with current through leads Iii extending out of the housing. The housing is constructed to provide three divergent passages l5, I6, and I1 for beams of radiation traveling away from the filament and the housing is made gas-tight by Windows I5a, ltd, and Ila at the ends of the respective passages. Windows i5a.,' Ita, and Ila and all other windows employed in the instrument are made of infrared transmitting materials, such as suitable crystals.

The beam issuing through window I5a enters a cell lll made of a metal tube closed at its oppositeends by anl entrance window I9 and an exit window 20, and the cell hasa gas inlet 2| containing a valve 22. The beam leaving cell I8 through the exit window-20 enters a cell 23 made of a metal tube Vclosed at one end by an entrance window 2li` and at the other by an exit window 25, and the cell is provided with a gas inlet'26 containing a valve 2l'. rl"he radiation issuing through window 25 enters a passage 28 in a filter cell generally designated 29 through an entrance window 23a.

Theradiation leaving passage I6 through the windowI l 5a enters a cell 30 made of a metal tube closed at one end by an entrance window 3l and at theother by an exit window v32 and the cell has a gas inlet 33 provided with a valve 34. The radiation leaving'cell ll'through window 32 enters the sample cell 35, which is made of a metal tube closed Vat one end by an entrance window 35 and at the other by an exit window 3l. Cell 35 has .aY gas outlet 38 provided with a valve 39 and is connected to cell 23 by a tubular connection flu. Cells 23 and together form a two-part sample cell and, in the use of the instrument, the mixture to be analyzed enters cell 23 through inlet 26, travels lengthwise through the cell, and then passes through connection 46 into cell 35, from which it leaves through the outlet 38. Preferably, inlet 26 and outlet 38 are at one end of the sample cell and connection 40 at the other, so that good flushing of the cell may be obtained and the development of stagnation points avoided. The radiation leaving cell 35 through window 31 enters passage 4I in lter cell 29 through the entrance Window 42.

Radiation leaving passage I1 through window I1a enters a cell 43 through entrance window 44 closing one end of the cell. The other end of cell fil-'5 is closed by a window 4,5 and the cell has a gas inlet 45a with a valve 45h. Radiation leaving cell 43 through window 45 enters a passage 46 in filter cell 29 through entrance window 41.

The filter cell 2S is provided with a gas inlet 48 having a valve 4S. The converging beams of radiation traveling through passages 28, 4I, and 46 in the lter cell enter the radiation receiving chamber 56 of a detector through an entrance window I.

The detector illustrated is of the selective type and measures radiation intensity by selective absorption by a gas with which a radiation receiving chamber of the detector is filled. Such energy absorption results in a pressure rise which produces an electrical variable, and, in the detector shown, the pressure rise actuates thin flexible membranes forming the movable plates of condensers connected in parallel, so that the electrical variable is a change in capacity. Static pressure differentials on opposite faces of each membrane are prevented by a capillary connecting the spaces on opposite sides of the membrane and only pressure fluctuations in a narrow range about the chopping frequency are measured.

The radiation receiving chamber of the detector is illustrated diagrammatically as including a central compartment 52 and outer compartments 53, 54 on opposite sides thereof. The compartments 52 and 53 are separated by a thin flexible metallic membrane 55 and a similar` membrane 58 separates compartments 52 and 54. The compartments are connected by a threeway connection 51 controlled by a valve 56 of such construction that all three compartments may be opened to one another or shut 01T from one another, A line 59 containing a valve 50 is connected to valve 58, so that, by opening valves 58 and 60, the three compartments may be evacuated, filled with gas at the same pressure, and then shut off from each other. A fixed plate 6I is mounted in compartment 53 is closely spaced relation to membrane 55 and, with that membrane, forms a variable condenser, and a xed plate 62 in compartment 54 cooperates with membrane 56 to form another variable condenser. The membranes are connected to a line 63 and the plates are connected to a line 64, so that the two condensers are in parallel.

The passage I5, the cells I8 and 23, and the passage 2S denne one path for a beam of radiation traveling from the source to the detector and this path may be referred to for convenience as the analysis path. The passage I6, the cells 36 and 35, and the passage 4I together dene a second path, referred to as the reference path, and the passage I1, the cell 43, and the passage 46 together define a third path, referred to as the nulling path. A manually adjustable trimmer 65 is mounted in each path and the trimmer takes the form of a metal plate, which can be moved in or out of the beam by an adjusting screw 65a (Fig. 3) to vary the intensity of the beam. The inner walls of the passages and cells are all highly polished for multiple reflections, but, if desired, such polishing may be dispensed with provided a focused optics system is used.

The beams traveling along the three paths are periodically interrupted at a low frequency, for example, from 3 to 20 cycles per second, by a chopper disc 66 (Fig. 2) mounted on a shaft 61 carrying a pulley 68 driven by a motor 69 through a belt 1I). The disc operates in the spaces between windows I5a and I9, I6a and 3|, and I1a and 44 and the disc is so formed and the radiation paths so disposed at the chopping plane that, as the disc rotates, it interrupts the analysis and nulling beams in unison and interrupts the reference beam out of phase with the other two.

The intensity of the beam of radiation traveling along the nulling path is controlled by a nulling trimmer 1I extending into the beam between windows I1a and 44 and lying at one side of the chopping disc. This trimmer may conveniently take the form of an annular strip of metal 12 (Fig. 4) supported by a radia1 arm 13 on a shaft 14, the strip having a width increasing from a minimum to a maximum with the edges of the strip symmetrical with respect to a circle concentric with shaft 14. The instrument functions within a pre-determined range set by the length of the sample cell and the taper in width of the nulling trimmer.

The lines 63, 64 leading, respectively, from the membranes 55, 56 and plates 6I, 62 of the condensers within the heat receiving chamber of the detector lead to a pre-ampliiier 15, which converts minute capacitance change into voltage change and may be an electrometer circuit or one of several well-known oscillator circuits. The voltage output from the pre-amplier is amplified by an A. C. amplifier 16, and the A. C. output from amplifier` 16 passes to a phase sensitive rectifier 11, which may be a mechanical breaker assembly or a generator and ring diode combination. The rectiner illustrated is of the latter type and the generator 18 is driven in synchronism with the chopper by being operated from the chopper shaft 61.

In the operation of the instrument with the beams being chopped, the variable condensers controlled by the pressure-actuated membranes in the heat receiving chamber of the detector produce phase sensitive information in the form of capacity changes, whenever the amount of energy in the reference beam differs from the total amount of energy in the analysis and nulling beams. Such phase sensitive information issues from the pre-amplifier in the form of a phase sensitive A. C. signal, which is amplied in the A. C. amplifier 1G. The output of the amplifier is then rectified in rectier 11 in such manner that the output of the rectier is a voltage of a polarity, which depends on whether the amount of energy transmitted along the reference path was greater than the total amount of energy transmitted along the analysis and nulling paths, or vice versa.

The polarized voltage from the phase sensitive detector is smoothed by filter 19 and is then fed to a servo amplifier 80, the output of which is supplied to a servo motor 8 I. The servo amplifier' and servo motor are so constructed that the shaft of the motor will rotate in one direction or the other depending on the polarity of the voltage suppl-iedby the phase sensitive'rectierll to the servo amplierf. The shaft of theservo motor 8l carries a pinionv82 meshing with-agearf' on shaft 'M of thevnulling trimmer 1| and'shaft M is connected tothe movingmember of a position indicating'slide wire device generally designated 84. This deviceis part of a circuit delivering an electrical signal corresponding to thevposition of the nulling trimmer '11, and is essentially a rotation-voltage transducer, which enablesaccurate indication of the position of the trimmer.. The output of the slide wire deviceis passed through lines 95,-89 to a iilter 81, which permits operation at acceptable noise levels,.and the filtered voltage may then be used for operating a recorder 88 or like device.

In setting up the instrumentforvthe analysis of Ya mixture containing'thegasof interest and an interfering component, the three compartments of the heat receiving chamber of the detector are lilled withthe gas of interest. at a predetermined pressure which givesmaximum detector sensitivity, such pressure'being-generally something less than atmospheric pressure. The cellf43 is lled with a non-interferinggasand preferably one which is infrarednon-absorbing, after which the nulling path throughcell 43 is blanked oif byfits trimmer .65. .The filter cell 29 is then either evacuated or filled with a nonabsorbing vgas through line 48 and valve t9 is closed, and the cells I8, 39 and the sample cell made up of parts 23 and 35v are either evacuated or lilled with a non-absorbing gas, as preferred. With the source i and chopperrSS functioning and the detector 53, pre-amplifier 15, and A. C. amplifier 7e in normal operation, the manual trimmer 95 in the reference path is adjusted, until the signal at the output of the A. C. ampliiier is reduced to zero, and the trimmer isthen locked in position. The'analysis and reference paths now transmit equal amounts of energy from the source to the detector.

The cell i8 in the analysis path is next filled with the gas of interestl preferably to atmospheric pressure to serve asa sensitizing cell and, thereafter, the interfering component is introduced at a partial pressure into cell 3,9 lying in the reference path and serving as a compensating or filtering cell. The partial pressure of the interfering component to be introduced into the compensating cell 39 must be determined by trial, but a partial pressure ofthis gas usually can be found, atwhich the instrument is compensatedso that it does not respond appreciablyto. changes in the concentrationof the interfering component present in the mixture to be analyzed. After the instrument has been compensated as described,.the milling trimmer 'li is adjusted, so that a given point thereon, for example, mid-scale, lies in the nulling path and the servo motor is shut oli'. A known sample, which may be the average composition of the mixture to be analyzed, is then introduced into the sample cells :23, 35., and the manual trimmer E in the nulling path is adjusted, until azero signal resultsl at the output of the A. C. amplifier. The instrument has now been brought to null condition for the standard sample and that sample. is removed.

The servo motor 8l is then turned on, and the unknown mixture is introduced into the sample cell'23, 35. Any variation in theamount of the gas of interest in the mixture from the amountcf that gasin the standardfsample at once produces-a phase sensitive..signal .at the output of the AfC. amplifier and .the,.phase. sen- 6. sitive rectier recties thefsignal andproduces a voltage of one polarity `or ithe other; depending upon whether 'more ener-gy -fwastransmitted #to the detector-along thelreference pathorlalo'ng the analysis` Vand nulling paths.v Thepolarized voltage is filteredand supplied 'to -thecservo Y' amplifier, the output of which is-passed to thev servo motor and causes that motor to rotatethe-trimmer in onel directionor the-'otheigdepending on the polarity of the voltage: supplied l'tol the servo amplifier, to vary thezintensity` ofithelbeam traveling alongthe nulling path. Themotor continues in operation until the: eutput'from'. the A. C. amplier is reduceditozero andtheadjustment of the trimmer freqnired'tofproduce-.this result results inthe production by thexpositioniindicating Yslide ywire device: of .ex-voltage, which is supplied to the recorder. .Thevalueof such'voltage is a measure .of theamountof .thegasfo'f interest present in themixture :beingv analyzed 'and the recorder is actuated'by the voltage .torecord the amount of the gas of interest.

In some cases, compensationof the instrument by introduction of the-interfering component into the compensating cell 3U.y cannot be exactly achieved and, in such instances, the elect of'a departure from exact cempensationcan be reduced by introducing some of the .interfering component into the fllterice1l29. The'presence of the filter gas infcell 29 reduces the -radiation intensityin the overlaperegion -andxreduces the unwanted signal. Where such -ltering is` required, the filter .gas is introducedintdcell 29 prior to the start-of the procedure employed in compensating.

In the instrument illustrated in vFig. l, the detector includesa single: chamber .59for receiving radiation and the radiation. paths areso ar ranged and the chopping disc r.S9-is ofsuchrform that the chamber receives radiation transmitted by the reference beam alternatelywith the total amount of radiation transmitted by the analysis and nulling beams. If desired, other .forms of detector may beused,4 such as-.that shown in the instrument of. Fig. 5.

The Fig. 5. instrument. is .illustrated .diagrammatically as including a .source .89..in vtheform of a heated filament mounted in a housing found .to provide three passages .91, .92, .93 for beams of radiation. The .beam .in passage 9| travels along a reference path,.including acompensating or filtering cell 94 similar in purpose andfunction to. cell 30, one part .95a.of artwopart sample cell 95,.and onepart 96a ofatwopart filter cell .96, and then-enters a radiation receiving chamber 191. The beam-.inpassage.92` travels along an analysis path includinga sensitizing cell 98 similar in purposeandfunction to cell i8, cell 95h connected to-cell 95a and formingthe second partof thesamplecell 95, and cell 962) connected to cell 9Sa.and.forming the second part .of .filter cell 96V. .The-.analysis beam then enters radiation.receiving.chamber 99. The beam in passage .93 travels valong a nulling path including acell |00 and .part 99h of the lter cell X96, and enters chamber .99.

The chambers 97 and .99 contain .they gasof interest at a suitable pressure and are connected through respective connections. IDI.,.H12 tochamber |93 on opposite sides of a flexible metal membrane |04, which cooperates .withaiixed plate E05 to form a variable condenser. YStatic pressure diierentials across l the. membrane; are eliminated by Aa .capillary con-nectiondi between chambers 91, 99. Themembrane and plateare connected by lines |01, |08 to a preamplifier |09.

The beams traveling along the three paths are periodically interrupted by a chopper disc H similar to disc 66, but the passages in housing 90 and the cells forming the paths are so a1'- ranged that the radiation is chopped in a cycle, in which all beams are simultaneously interrupted and then are simultaneously passed. As a result, the radiation in the reference beam enters chamber 91 at the same time that the radiation in the analysis and nulling beams is entering chamber 99. The beams entering the chambers cause a rise in pressure in each chamber and the pressures in the chambers act on opposite faces of the membrane to produce a change in capacity of the variable condenser formed by the membrane and the fixed plate. The capacity changes corresponding to the differences in the pressure rises in the chambers are phase sensitive and are converted into voltage changes in the pre-amplifier. The output of the pre-amplifier is a phase sensitive electrical signal which is utilized in the same manner as the signal produced by the pre-amplifier 15 in the instrument shown in Fig. 1; that is, the signal is amplified in the A. C. amplifier HI and rectified in the phase sensitive rectifier |2. The output of the rectifier is a polarized voltage, the polarity of which depends on whether the energy in the reference beam was greater than the total amount of energy in the analysis and nulling beams, or vice versa. After being smoothed by filter H3, the polarized voltage is fed to a servo amplifier H4, the output of which is supplied to a servo motor H5. The servo motor operates in the same manner as servo motor 8|, rotating in one direction or the other, depending on the polarity of the voltage supplied by the phase sensitive rectifier ||2 to the servo amplifier H4.

The servo motor operates through gearing H3 to drive the shaft H1 of a nulling trimmer H8 lying in the path of the nulling beam and similar in purpose and function to the nulling trimber 1|. Shaft ||1 also operates the moving member of a position indicating slide wire device, generally designated H9 and forming part of a circuit delivering an electrical signal corresponding to the position of the nulling trimmer I8. The output of the slide wire device is passed to a filter |20 and the filtered voltage may then be used for operating a recorder |2| or like device.

In the instrument shown in Fig. 1, the chopper 66 causes the chamber 50 to receive radiation transmitted along the reference path in alternation with radiation transmitted simultaneously along the analysis and nulling paths and the membranes and fixed plates within chamber 50 produce phase sensitive information. In the Fig. instrument, the use of the chopper causes the membrane |05 to respond to differential pressure fiuctuations in a narrow frequency range about the chopping frequency and phase sensitive information is again produced.

The instrument shown in Fig. r1 is similar to that shown in Fig` 5, except that a different form of detector is employed, and the parts of the Fig. '1 instrument, which are the same as those in the instrument of Fig. 5, are identified by the same reference characters, to which prime marks have been added. In the instrument of Fig. '1, the detector includes a radiation receiving chamber |22 for the reference beam and the chamber contains an inner compartment |23 closed at one end by a flexible metallic membrane |24. The membrane separates compartment |23 from an outer enclosing compartment |25 and the two compartments are connected by a capillary connection |26 to avoid static pressure differentials on opposite faces of the membrane. The membrane cooperates with a fixed plate |21 to form a variable condenser. The detector includes a second radiation receiving chamber |28 having an inner compartment |29, which receives the radiation in the analysis and nulling beams and is closed at one end by a thin flexible metallic membrane |30. Compartment |29 lies Within an outer compartment |3| containing a fixed plate |32 cooperating with the membrane to form a variable condenser, and the two compartments are connected by'a capillary connection |33.

The variable condensers in the chambers |22, |28 are connected in a conventional subtraction network indicated at |34, and the output from the network passes to a pre-amplifier |35, the output of which is a phase sensitive electrical signal. The signal is amplified in the A. C. amplifier |36 and delivered to a servomotor |31, which rotates in one direction or the other, depending on the phase of the signal, which, in turn, depends on whether more radiation was transmitted by the reference beam than the total amount of radiation transmitted by the analysis and nulling beams, or vice versa. The servomotor operates through gearing H6 to drive the shaft H1' of a nulling trimmer H8 in the nulling path, and shaft H1 also operates the moving element of a position indicating slide Wire device H9. The output from the slide wire device is filtered in lter |20 and employed in any desired Way, as, for example, to operate recorder |2I. Instead of employing the subtraction network shown in Fig. 1, the instrument may employ an addition network with a `chopper of appropriate form.

The methods of setting up and utilizing the instruments of Figs. 5 and '1 in analytical work are the same as those described in connection with the instrument of Fig. 1.

It is to be understood that the position indicating slide Wire combination employed in the three forms of instrument illustrated and described, it is not necessarily a proportional device. The absorption of radiation by the component of interest is not a linear function of concentration. Accordingly, when a recorder is employed, it may sometimes be desirable to make use of a non-linear slide wire of such construction that the relation between the recorder scale and the concentration of the component of interest in the sample is linear. The electrical network associated with the slide wire may be any one of several well-known networks, and may be either A. C. or D. C., as desired.

The nulling trimmer, such as trimmer 1|, is illustrated as having a tapering width with its edges symmetrical with respect to a circle concentric with its shaft. When the taper in width is slight, one edge of the trimmer may be circular and the opposite edge formed to provide the taper. Also, in some cases, it may be desirable to form the trimmer of non-uniform taper.

The choppers disc, such as disc 6B, are ordinarily made of opaque material but, for some purposes, the disc may be made of a known material having the characteristic of transmitting radiation above a specific wavelength only.

The instruments illustrated and described are for use in the infrared field and, when `ultra violet radiation is to be employed, an appropriate aeefsgoeo 9` source will be used and obvious changes will be required in the window materials and' the detector.

The novel features, such as the detector shown in Fig. 1, which are disclosed but not claimed herein, form no part of the present invention and are disclosed and claimed in the co-pending application of Elliot W oodhull, Ser. No; 334,144, led January 30, 1953, or in the co-pending application of Woodhull, Borden, and'Montpas, Ser. No. 334,143, iiled January 30, 1953'.

We claim:

1. In a radiation instrument including means for causing beams of radiation to travel along two different paths, the secondbeam being weaker than the first, and means for causing a third beam to travel along a path different from the rst two paths, the combination of means for interrupting the beams periodically, the second andi third beams being interrupted simultaneously, detecting means acting in response to radiation in the beams falling thereon to produce a phase sensitive electrical signal, adjustable means for varying the intensity'of the third beam, means ac-ting in response to said phase sensitive signal to adjust said intensity varying means to cause said signal to be reduced to zero, and means actuated by said adjusting means and producing a response corresponding to the adjustment of said intensity varying means.

2. In a radiation instrument including means for causing beams of radiatio-n to travel along two diierent paths, the second beam being weaker than the first, and means for causing a third beam to travel along a path diierent from the rst two paths, the combination of means for interrupting the beams periodically, the second. and third beams being interrupted simultaneously, detecting means, including means receiving the radiation in the beams and producing an electrical variable and means converting the variable into a phase sensitive electrical signal, adjustable means for varying the intensity of the third beam, means acting in response to said phase sensitive signal to adjust said intensity varying means to cause said signal to be reduced to zero, and means actuated by said adjusting means and producing a response corresponding to the adjustment of said intensity varying means.

3. In a radiation instrument including means for causing beams of radiation to travel along two different paths, the second beam being weaker than 'the rst, and means for causing a third beam to travel along a path different from the iirst two paths, the combination of means for interrupting the beams periodically, the second and third beams being interrupted simultaneously, detecting means, including means receiving radiation in the beams and producing capacity changes and means converting said capacity changes int-o a phase sensitive electrical signal, adjustable means for varying the intensity of the third beam, means acting in response to said phase sensitive signal to adjust said intensity varying means to cause said signal to be reduced to zero, and means actuated by said adjusting means and producing a response corresponding to the adjustment of said intensity varying means.

4. In a radiation instrument including means for causing beams of radiation to travel along two diiTerent paths, the second beam being weaker than the rst, and means for causing a third beam to travel along a path different from the rst two paths, the combination of means for interrupting the beams periodically,v the second and third zbeams being interrupted simultaneously, detecting means acting in response to radiation in the beams falling thereon to produce a phase sensitive electrical signal, adjustable means for varyingthe intensity of the third beam, means operating in response -to said signal and producing a voltage polarized in accordance with the phase of the signal, means operating in response to the polarity of said voltage to adjust said intensity varying means to cause said signal to be reduced to zero, and means actuated by said adjusting means and producing a response corresponding to the adjustment of said intensity Varying means.

5. In a radiation instrument including means for causing beams of radiation to travel along two different paths, the second beamfbeing weaker than the rst, and means for causing a third beam to travel along a path different from the rst two paths, the combination of means for interrupting the beams periodically, the second and third beams being interrupted simultaneously, detecting means acting in response to radiation in the `beams falling thereon to produce a phase sensitive A. C. signal, means for amplifying said signal, means for rectifying the output of the amplifying means and producing a voltage of a voltage polarized in accordance with the phase ofv said signal, adjustable means for varying the intensity of the third beam, meansoperating in response to the polarity of said voltage to adjust said intensity varying means te cause said signal to be reduced to zero, and' means actuated byv said adjusting means and producing a response corresponding to the adjustment of said intensity Varying means.

6. In a radiation instrument including means for causing beams of radiation to travel along two diierent paths, the second beam being weaker than the first, and means for causing a, Ithird beam to travel along a path different from the rst two paths, the combination of means for interrupting the beams periodically, the second and third beams being interrupted simultaneously, detecting means acting in response to radiation in the beams falling lthereon to produce a phase sensitive electrical signal, an adjustable trimmer for varying the intensity of the third beam, means acting in response to said phase sensitive signal to adjust said trimmer to cause said signal to be reduced to zero, said means including a servomotor connected t0 the trimmer, and means actuated by said adjusting means and producing a response corresponding to the adjustment of said intensity varying means.

7. In a radiation instrument including means for causing beams of radiation to travel along two different paths, the second beam being weaker than the rst, and means for causing a third beam to travel along a path diierent from the first two paths, the combination of means for interrupting the beams periodically, the second and third -beams being interrupted simultaneously, detecting means acting in response to radiation in the beams falling thereon to produce a phase sensitive electrical signal, adjustable means for varying the intensity of the third beam, means acting in response to said phase sensitive signal to adjust said intensity varying means to cause said signal to be reduced to zero, and means actuated by said adjusting means and producing a voltage related to the adjustment of said intensty varying means.

8. In a radiation instrument including means for causing beams of radiation to travel along two different paths, the second beam being weaker than the rst, and means for causing a third beam to travel along a path different from the rst two paths, the combination of means for interrupting the beams periodically, the second and third beams being interrupted simultaneously, detecting means acting in response to radiation in the beams falling thereon to produce a phase sensitive electrical signal, adjustable means for varying the intensity of the third beam, means acting in response to said phase sensitive signal to adjust said intensity varying means to cause said signal to be reduced to zero, means actuated by said adjusting means and producing a voltage corresponding to the adjustment of said intensity varying means, and recording means operated by said voltage.

9. In a radiation instrument including means for causing beams of radiation to travel along two dierent paths, the second beam being weaker than the first, and means for causing a third beam to travel along a path different from the rst two paths, the combination of means for interrupting the beams periodically, the second and third beams being interrupted simultaneously, detecting means acting in response to radiation in the beams falling thereon to produce a phase sensitive electrical signal, a trimmer for varying the intensity of the third beam, means acting in response to said phase sensitive signal to adjust the trimmer to cause said signal to be reduced to zero, and means actuated by said adjusting means and producing a response corresponding to the adjustment of the trimmer.

10. In a radiation instrument including means for causing beams of radiation to travel along two different paths, the second beam being weaker than 'the rst, and means for causing a lthird beam to travel along a path different from the first two paths, the combination of means for interrupting the beams periodically, the second and third beams being interrupted simultaneously, detecting means acting in response to radiation in the beams falling thereon to produce a phase sensitive electrical signal, adjustable means for varying the intensity of the third beam, means acting in response to said phase sensitive signal to adjust said intensity varying means to cause said signal to be reduced to zero, and means, including a circuit containing a position indicating slide wire, operated by said adjusting means and producing a response corresponding to the adjustment of said intensity varying means.

l1. In a radiation instrument including means for causing beams of radiation to travel along two dierent paths, the second beam being weaker than Ithe rst, and means for causing a third beam to travel along a path diierent from the first two paths, the combination of means for interrupting the beams periodically, the second and third beams being interrupted simultaneously and out of phase with the rst beam, detecting means, including a radiation receiving chamber receiving all the beams, said detecting means acting in response to radiation in the beams to produce a phase sensitive signal, adjustable means for varying the intensity of the third beam, means acting in response to said phase sensitive signal to adjust said intensity varying means to cause said signal to be reduced to zero, and means actuated by said adjusting means and producing a response corresponding to the adjustment of said intensity varying means.

No references cited. 

